EP1198711A1

EP1198711A1 - Method for diagnosing cancerous diseases and/or neuro-degenerative pathological conditions and products therefor

Info

Publication number: EP1198711A1
Application number: EP01927852A
Authority: EP
Inventors: Oliver Nayler; Stefan Stamm; Annette Hartmann
Original assignee: Max Planck Gesellschaft zur Foerderung der Wissenschaften eV
Current assignee: Max Planck Gesellschaft zur Foerderung der Wissenschaften eV
Priority date: 2000-04-03
Filing date: 2001-04-02
Publication date: 2002-04-24
Also published as: AU5476601A; DE10016527A1; WO2001075441A1

Abstract

The invention relates to a method for diagnosing cancerous diseases and/or neuro-degenerative pathological conditions. According to said method, proteins with domains rich in glutaminic acid/arginine or asparaginic acid/arginine, (ER proteins or DR proteins), are determined. The concept of determining ER or DR proteins is also suitable for investigating the transcription activity, the differentiation stage and/or the cell cycle stage of a cell and for testing therapeutically active substances. The invention also relates to useful products for use in said methods.

Description

Methods for diagnosing cancer and / or neurodegenerative conditions and products therefor

description

The present invention relates to methods for the investigation of cancer and / or neurodegenerative disease states. These include in particular diagnostic methods and methods for testing therapeutically active substances against the above-mentioned diseases. The invention further relates to products which are particularly suitable for use in the abovementioned examinations or processes.

Previously known examinations, procedures and products for the disease states mentioned at the beginning are very heterogeneous and complex. Over the course of time, a large number of so-called tumor markers for cancer have been discovered and used for diagnostic purposes (see, for example, the overview literature in J. Natl. Cancer Inst., Vol. 80, pp. 722-727 (1988) as well as Cimono (ed.), Human Tumor Markers, De Kreuther Verlag (Berlin) (1987), in which primarily tumor-specific or tumor-associated antigens are detected using immunological methods.

Recently, in the field of tumor diseases, special attention has been paid, both from a diagnostic and therapeutic point of view, to the structure of the cell nucleus and possibly related, relevant cell nucleus components (see JA Nickerson in Journal of Cellular Biochemistry, Vol. 70, Pp. 172-180 (1998)). Two fundamental characteristics of malignant changes appear to stand out particularly clearly there, namely changes in the architecture of cells and tissues and the genetic instability. The observation of cell type-specific nuclear matrix proteins led to US Pat. Nos. 4,885,236 and 4,882,268, which describe the use of such nuclear matrix proteins for cancer diagnosis. However, the methods described there are complicated and labor-intensive. They require the isolation of internal nuclear matrix proteins and their separation, usually via two-dimensional gel electrophoresis, after which the analysis image obtained in this way is compared with normal standards in order to be able to identify malignant states. Such methods are therefore not suitable for routine use, for example as a screening assay.

Diagnostic concepts based on the nuclear matrix have therefore not found their way into clinical practice. YES. Nickerson (see above) attributes this to the previous inability to identify tumor-specific or -associated polypeptides of the cell nucleus. The relatively low exposed amounts of such polypeptides are also considered problematic. Furthermore, J.A. Nickerson reports that a test against nuclear matrix proteins based on the NMP22 anti- gene could have a value in addition to cytological and endoscopic examinations accompanying the follow-up after the treatment of patients with bladder cancer. However, the target antigen NMP22 is not considered to be specific for a malignant or transition state of cells. In addition to this lack of specificity in existing methods, a further problem is seen in the fact that assay formats normally carried out, such as immunocytochemical and serum-based assays, cannot be used there.

It is therefore an object of the present invention to expand and improve the possibilities for diagnosing diseases, particularly cancer. The inventors surprisingly found that proteins with glutamic acid / arginm-rich domains (so-called ER proteins) or with aspartic acid / arginm-rich domains (so-called DR proteins) represent new and meaningful markers for the development of pathological conditions. It was also found that the pathological conditions affected can not only be cancerous diseases but also neurodegenerative diseases, which even further increases the diagnostic significance of the marker found. At the same time, it was surprisingly recognized that changes in the aforementioned ER proteins or DR proteins after exposure to certain substances can be an indication that the substances used are therapeutically effective against diseases, in particular against cancer and / or neurogenerative disease states.

The invention accordingly provides a method for the diagnosis of cancer and / or neurogenerative disease states in which proteins with domains rich in glutamic acid / arginm (hereinafter ER proteins) or domains rich in aspartic acid / argin ( hereinafter briefly: DR proteins) can be determined.

This determination method is also suitable for examining the transcription activity, the differentiation stage and / or the cell cycle stage of a cell.

In a further object, the invention provides a method for testing therapeutically active substances against cancer and / or neurodegenerative disease states, which the examination a change in ER proteins or DR proteins as a result of exposure to such potentially therapeutically active substances.

The invention further provides useful products which are particularly well suited for use in the method described above. These include, in particular, antibodies specific to an ER protein or a DR protein, as well as a mammalian cell that is transformed by a DNA that codes for an ER protein or DR protein. In further objects of the present invention, these special products are used in the above-mentioned processes.

The invention is explained in more detail below with reference to the figures.

Figure 1 shows examples of some ER or DR proteins that can be determined in the context of the present invention, where A is a schematic line representation of the respective protein structure (with the ER or DR domain in the form of a black box) and B the sequence -Alignment with respect to the conserved ER or DR domain region with the consensus sequence shows.

FIG. 2 shows the results of immunohistochemical staining of an ER protein as a marker for normal cells (A), for tumor cells (B, left column) and for treated tumor cells (B, middle and right columns).

FIG. 3 shows the overall domain structure of an ER protem using the example of YT521-B.

Figure 4 shows the results of immunocytometric studies on a mammalian cell (COS7 cells) according to the present invention is transformed with an ER or DR protein-encoding DNA and has been treated with different transcription or transplantation inhibitors.

ER and DR proteins, with their respective ER and DR repeat units, are expressed in a variety of body tissues, including the brain. The ER and DR-rich domains seem to be responsible for the nuclear localization of these proteins. Some members of the family, such as YT 521-B, primarily m cells of neuronal origin are found there.

Figure 1 shows an exemplary series of ER and DR proteins that can be considered for the present invention. The corresponding DNA or polypeptide sequences can be obtained from known gene banks (e.g. "GenBank") using the names of the proteins given in FIG. 1.

The proteins are shown as lines in FIG. 1A, the regions rich in ER or DR being shown as a black box. The scale line stands for 100 amino acids long. FIG. 1B shows the comparison of the areas rich in ER or DR (domains) from A). The names of the respective proteins stand for:

KIA 0182 = hypothetical protein (T. Nagase et al. In DNA Res. Vol. 3, pp. 17-24 (1996); Disc = drosophila disconnected gene (JS Heilig et al., EMBO J. Vol. 10, p. 809-815 (1991)); RD-Prote = Human RD-Protem (CS Surovi et al., Gene vol. 90, pp. 299-301 (1990)); RNA-Helicase I = RNA-Helicase-isolo from Arabidopsis taliana (Genbank accession number U78721); IK factor = human IK factor (P. Greve et al., Oncogene Vol. 9, pp. 3449-3456 (1994)); U2AF = U2 auxiliary factor from tobacco (C. Domon et al., J. Biol. Chem. Vol. 273, Pp. 34603-34610 (1998)); Shuttle Craft = "Shuttle Craft" protein from Drosophila (ND Stroumbakis, Mol. Cell Biol. Vol. 16, pp. 192-201 (1996)); J170K = human Ul70K protein (RA Spritz et al., Genomics Vol. 8, pp. 371-379 (1990)); YT521-B = Splic g-associated factor (AM Hartmann et al., Mol. Biol. Cell, Vol. 10, pp. 3909-3926 (1999); Genbank Accession No. AF 144731); SRP20 = SRP20-like protein from C. elegans (R. Wilson et al., Nature Vol. 368, pp. 32-38 (1994)); RNA Helicase-II = RNA Helicase ATP-dependent RNA Helicase HRH1 (M. Ono and Y. Shimura, Genes De. Vol. 10, pp. 997-1007 (1996)); Hei 117 = rat RNA helicase (J. Sukigawa and G. Blobel, J. Biol. Chem. Vol. 270, 15702-15706 (1995)) Octapep-Prot. = Mouse octapeptide protein (N. Di Carlo et al., J. Submicrosk. Cytol. Pathol. Vol. 24, pp. 467-472 (1992)); Rat SAF-B = "Scaffold Attachment Factor B" (0. Nayler et al., Genomics Vol. 53, pp. 191-202 (1998)). Proteins were determined using the last 60 amino acids of YT521-B and sequence (ER) ₁₅ using the BLAST algorithm. Similar sequences were put together using the PILEUP program. The expression "consensus" means the consensus sequence of this comparison determined by means of LINE UP.

Some of these proteins, such as the RD-Protem, U170K, SAF-B, the "Shuttle Craft" -protem, SRP 20, U2-Auxιlιary Factor and several RNA helicases are involved in the Pra-mRNA splicing process or in the formation of the transcriptosomal Complex involved. It is assumed that the ER or DR proteins perform important functions. Certain proteins thereof interact with each other. This was by AM Hartmann et al. m Molecular Biology of the Cell 10, pp. 3909-3926 (1999) using the example of the YT521-B proteme, which interacts with the nuclear transcriptosomal component SAF-B, while a further interaction of YT521-B with the p62 / SAM 68-Protem also plays a role in its biological function seems to be playing. The ER or DR-rich region appears to be important for the biological function, since deletion variants without these regions abolish the detectable binding to other interacting proteins. There is also evidence that this characteristic domain is important for the subnuclear occurrence and the splice pattern of reporter genes.

The localization of the ER or DR proteins in concentrated areas (dots, "dots" or "bodies") or the change in such a state has now emerged as a distinctive sign of disease. The examination according to whether or to what extent the ER or DR proteins can be localized in such cellular, nuclear areas has turned out to be particularly meaningful for the diagnostic method or the test method according to the present invention. It was found that cells in the normal state had several such localizable areas, as shown in FIG. 2A. In contrast, such concentrated areas surprisingly m

Tumor cells do not show up, as shown in FIG. 2B for the human tumor cell line MCF7. Rather, the ER or DR protein is diffusely distributed in the cell nucleus.

For neurodegenerative conditions or diseases, on the other hand, an increase in the number of localizable, nuclear areas with respect to ER or DR proteins has surprisingly been observed. A number of neurodegenerative diseases are triggered by the expansion of triplet repeats. These include, for example, spinocerebellar ataxia type 1 and Huntmgton's disease (MIM / OMIM numbers 164400 and 143100). The associated gene products, sca-1 and Huntmgtm have a formation of nuclear points (PJ Skmner et al. Nature 389, pp. 971-974 (1997) [published Erratum in Nature 391, p. 307 (1998)], L. Roizin et al. Adv. Neurol. 23, pp. 95-122 (1979)), which are very similar to the structures formed by ER protems (E. Assier et al. Gene 230, pp. 145-154 (1999)). A protein which interacts with YT521-B, DAN26 (Genbank reference number U94836) also interacts with sca-1 and leads to a translocation of the sca-1 gene product containing yT521-B core structures. Detection of core structures that can be positively detected with regard to ER or DR prototypes such as YT 521-B can thus also be advantageous for the genesis and diagnosis of neurodegenerative diseases such as spmocerebellar ataxia type 1 and Huntmgton's disease.

Thus, the determination of the ER or DR proteins with regard to distribution, localization in the nuclear areas of the cell nucleus and quantification provides very useful information and diagnostic statements. In the method according to the invention, one or more ER or DR protems can be determined. The investigation for the DR prototype YT521, in particular its splice variant YT 521-B, has proven to be particularly informative.

Furthermore, it was found in the context of the present invention that the occurrence of the ER or DR proteins in localized nuclear areas during the course of the

Cell cycle is regulated and changing. The occurrence of the localized areas correlates very well with the beginning during the middle to late Gl phase and the subsequent continuation during the S phase with respect to the transcriptional activity, while such localizable areas during mitosis, especially G2 / M- Phase and the early Gl phase, were undetectable and thus indicated the lack of transcriptional activity. The determination of the ER or DR proteins, in particular the localizable occurrence in cellular, nuclear areas, can therefore be more advantageous In this way, it can also be used to determine the transcription activity, the differentiation stage and / or the cycle stage of a cell to be examined.

Another possible use of the marker described above, according to the invention, i.e. of the ER or DR protein (s) described above consists in testing therapeutically active substances, in particular those against cancer and / or neurogenerative disease states. Therapeutic effectiveness is shown by the fact that the appearance of the ER or DR proteins as described above changes as a result of the action of the investigated, potentially therapeutically active substance. Meaningful criteria for such a change are in turn a diffuse distribution, a visualization in defined nuclear areas or an increase in such nuclear areas on ER or DR proteins. This was demonstrated experimentally using the example of the well-known breast cancer cell MCF7. While the untreated cancer cell lines showed only a diffuse distribution of ER or DR proteins and no occurrence of nuclear areas, such nuclear areas could be localized after 48 hours of incubation with the well-known anti-breast cancer agent tamoxifen (see Fig. 2B, left and right column). The effects of known differentiation agents such as Natπumbutyrat or Phorbol-12-myrιstat-13-acetate (PMA) also changed the appearance with the appearance of the localizable, nuclear areas after the treatment (see FIG. 2B, the two middle columns).

For the detection within the framework of the determination of the ER or DR protems in the methods according to the invention, primarily immunocytic and related methods come into question, as was the case with the experiments described above. Immunocytic methods are advantageously measured using the assay formats customary in the Screenmg method. However, other typical, specific protein detection methods also come into question, for example an enzyme-linked immunosorbent assay (ELISA). Such methods are familiar to the person skilled in the art.

Antibodies which are directed against one or more of the ER or DR proteins described above can be mentioned as particularly useful products for use in such immunocytic processes or the like. The antibodies can be directed against the entire ER or DR protein or against an oligopeptide which defines a sequence section from the ER or DR protein. Depending on the desired application, the antibodies can be directed against the ER or DR region, so that ER or DR proteins can generally be detected. For this purpose, the consensus sequence shown in FIG. 1B can be used as the antigen. On the other hand, it can, if desired, be advantageous if the antibodies are specifically directed against individual ER or DR proteins in order to enable more differentiated statements to be made. This is shown in Example 2 for an anti-body against YT521-B. The antibodies of the invention can take any form: monoclonal or polyclonal, also smgle chain, in hybrid or combinatorial form.

According to the invention, a further useful product is a mammalian cell which is transformed by a DNA which codes for an ER protein or DR protein as described above. The mammalian cell is preferably of human origin. Such a transformed cell can advantageously be used for the method described above for testing therapeutically active substances, in particular those for cancer diseases and / or neurodegenerative disease states become. The transformation of the mammalian cell with the DNA encoding the ER or DR protein can be carried out using methods known per se (see, for example, J. Sa brook et al., Molecular Clonmg, Cold Spring Harbor Laboratory Press (1989)). Suitable vectors, including expression-demanding sequences, are known and are described in J. Sambrook et al. described. The DNA coding for the ER protein or DR protein is preferably stably integrated into the genome of the mammalian cell.

The above-described methods according to the invention can be carried out without difficulty, for example after removing a suitable cell material from the patient to be examined or by using cells brought into culture. In particular for the test method according to the invention for screening potentially therapeutically active substances, it is preferred to use established cell lines which are specific for the respective disease state in a suitable manner.

The invention is described in more detail below with the aid of illustrative but not restrictive examples.

Example 1:

Cloning of an ER or DR protein encoding DNA

The molecular cloning was carried out using the example of YT521-B using standard protocols (J. Sambrook et al., Molecular Clonmg, Cold Spring Harbor Laboratory press

(1989)). Reverse transceptase (RT) - PCR was carried out as by AM Hartmann and S. Stamm (Biochem. Biophys. Res. Com. Vol. 1353, pp. 224-230 (1997)). Genebanks from rat brain, one postnatal (day 5) and the other in the embryonic state after 16 days, became one Doppelhybπd-Screenmg using an htra2-ß pGBT9 probe (B. Beil et al., DNA and Cell Biol., Vol. 16, pp. 679-690 (1997)) as bait. The yeast Gal4 double hybrid screen was designed according to S. Fields and 0. Song. (Nature Vol. 340, pp. 245-247 (1989)) using the HF7c strain. For each screen, approximately 6 × 10 ⁶ transformants were screened with 100 μg bait (bai t) DNA and 50 μg prey (prey) DNA. In order to test an interaction of YT521-B with other proteins, 1 μg of the YT521-B fused with the Gal4 activation domain and 1 μg of SAF-B, htra2-beta, hnRNP-G, p62 / SAM68 and with the Gal4- Bmdungsmomane fused YT521-B were cotransformed and plated on triple dropout plates lacking Leucm, Tryptophan and Hystidm. Surviving colonies were stripped repeatedly on triple dropout plates supplemented with 10 mM 3-ammotnazole.

DNA was isolated from His-autotrophic and lacZ-positive colonies (CS Hoffmann and F. Wmston, Gene, Vol. 57, pp. 267-272 (1987)), introduced into HBIOI cells by electroporation, after which selection was carried out on Ampicillm plates has been. Resistant colonies were swabbed onto M9 plates without Leucm to remove Koder plasmid (S.M. Hollenberg et al., Mol. Cell Biol., Vol. 15, pp. 3813-3822 (1995)). DNA from the autotrophic bacteria was isolated and under

Sequenced using an automatic sequencer (ABI sequencer). The DNA sequences were analyzed with the GCG-Wisconsm software package (Genetics Computer Group, Program Manual for Wisconsin Package, Version 8, Medic e, Wisconsin (1994)).

Two cDNA clones, YT521TH-pADgal4 and YT521ΔN10-pADGal4, were obtained. Since none of the clones contained a complete cDNA, rapid amplification of cDNA ends (RACE) was carried out to amplify the missing 5 'ends (marathon cDNA a plication kit; Clontech). A comparison with the complete RACE clones showed that the first clone lacked the first 253 amino acids and the second clone lacked the first 10 amino acids. YT521TH-B and YT521ΔN10 were cloned in the form of an EcoRI / SacII fragment in pEGFP-C2 (Clontech) and in the form of an EcoRI / PstI fragment in pGBT9 (Clontech). Restriction sites were introduced by means of PCR amplification with the oligonucleotides yt521eco-fl: CCGAATTCTATGAACAGGATGAGAGAGATC (SEQ ID No. 1), yt521-sacll-r: CCCCGCGGACATTATCTTCGATAACGACCTCTTTCC (SEQ IDGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTt 3).

A cloning similar to the above procedure by Y. Imai, et al., Mol. Brain Res. Vol. 53, pp. 33-40

(1998)) recently led to the isolation of a similar cDNA, YT521.

The overall domain structure of the ER prototype YT521-B found is shown in FIG. 3A. The ammotermmal, glutammic acid-rich region, the carboxyterm ale prolm-rich region and the characteristic glutammic acid / amm-rich region are indicated by shaded boxes. The boxes with Arabic numbers indicate the four nuclear localization signal sequences. The letters "A" and "B" denote the insertions that are likely to be generated by alternative splicing. The detailed sequences of insertions A and B are given below the representation of the overall domain structure (both DNA and letter E ammosaic sequence). The protein YT521-B differs from YT521 by these insertions A and B. The total sequence of YT521-B was filed in the gene bank under the accession number AF144731. Northern blot analyzes m-tu hybridization studies on brain tissue sections showed that YT521-B occurs in different types of tissue (heart, brain, kidney, lung, liver, muscle, spleen and testis), whereby different isoforms were discovered due to alternative splicing ), whereby a cell type-specific expression was characteristic in the brain.

Example 2

Production of antibodies against ER or DR proteases

Antibodies were obtained using conventional methods against antigenic structures of the ER or DR proteases. For example, a rat polyclonal antibody specific to YT521B was developed, against a mixture of two YT521-B-specific polypeptides, each of which had been fused with the keyhole limpet hemocyanin, namely polypeptide No. 1: RSARSVILIFSVRESGKFQCG (SEQ ID No. 4), and polypeptide No. 2: KDGELNVLDDILTEVPEQDDECG (SEQ ID No. 5).

Example 3 Immunocytological Determination of ER or DR Protemen

1. Cell culture

Cells such as HEK293, COS7 cells or BHK cells were kept in Dulbecco's modified Eagle's Medium (DMEM) to which 10 (v / v)% fetal calf serum (FCS) was added. The human breast cancer cell MCF7 was kept in RPMI 1640, which was supplemented with 10% (v / v) FCS. For immunological staining experiments, cells were grown on glass cover plates in 6 cm cell culture vessels. 2. Cell nucleus extraction

Nuclear extractions were carried out as described (see, for example, M. Patturajan et al., Mol. Cell. Biol., Vol. 1998, pp. 2406-2415). Briefly, cells were in Tris buffered salt (TBS buffer: 10mM Tπs-HCl, pH 7.4, 150mM NaCl, 5mM MgCl ₂ ) containing 0.5% Tπton-X 100 and 0.5mM PMSF contained, permeabilized. The cells were then incubated in TBS alone, in TBS with 20 U / ml benzonase or in TBS with 4 U / ml DNase-free RNase (the enzymes were obtained from Sigma). Finally, cells were extracted with TBS / 0.2 M ammonium sulfate, fixed in 3.7% formaldehyde / phosphate-buffered salt (PBS) for 5 minutes and, if necessary, with the dye Hoechst No. 33258 in a concentration of 1 μg / ml PBS incubated.

3. Cell cycle analysis

Cells were grown to 60-80% confluency and blocked with 0.5 μg / ml nocodazole for 4 hours in the G2 / M phase. Mitose cells were then collected by collecting on the cell culture vessel, washed and seeded on glass cover plates (DL Spector et al. M Cells: A Laboratory Manual; Cold Spring Harbor Laboratory Press, New York (1998)). The cells were incubated for 6, 13, 18 and 24 hours before fixation. 4. Immunocytic staining

1 x 10 ⁵ cells to be examined were grown on a glass cover plate 3.5 cm culture dish for 24 h before fixation and immunostaining. The cells were then fixed in 3.7% formaldehyde in PBS for 10 minutes at room temperature, washed three times in PBS / 0.1% Tπton-XlOO and m PBS / 0.1% Tπton-X 100/3% bovine serum albumin blocked for 30-60 minutes at room temperature. The cells were then incubated with the appropriate antibody, here the antibody against YT521-B obtained according to Example 2, overnight at 4 ° C. in PBS / 0.1% Triton-X 100/3% bovine serum albumin and three times washed with PBS / 0.1% Triton-X 100. The cells were then incubated with CY3-conjugated secondary antibody (Dianova) PBS / 0.1% Triton-X 100 for 2 hours at room temperature, washed three times with PBS / 0.1% Tπton-X 100 and on glass plates with Fluormount ( Dianova) pinned. The cells were examined either by laser scanning fluorescence microscopy (Leica) or by conventional microscopy, followed by a deconvolution process using Openlab software (Improvision).

Example 4 Cancer diagnosis using the example of breast cancer

1 x 10 ^{6 of} the human breast cancer cell MCF7 were seeded in 10 cm cell culture dishes containing 4 glass cover plates and grown for 24 h. After a further 48 h, the glass cover plates were removed and the cells were fixed as described in Example 3, item 4 and stained using the antibody described in Example 2. The immunofluorescence examination using laser scanning fluorescence microscopy showed a diffuse nuclear staining of the endogenous ER prototype in the untreated MCF7 cells; no defined nuclear areas could be localized (see FIG. 2B on the left). In comparison, normal cells (here: BHK and COS cells) showed the characteristic spot staining ("dots") that could be located in the cell nucleus (see FIG. 2A).

Example 5

Cell differentiation and therapeutic treatment

In order to show that the detection of ER or DR proteins is suitable for studying cell differentiation and for testing therapeutically active substances, MCF7 cells were grown as described in Example 4 and treated with different agents.

For this purpose, after sowing and growth for 24 hours, the MCF7 cells were incubated with t tamoxifen (5 μM), sodium butyrate (1 μM) or phorbol-12-myristate-13-acetate (PMA, 1 μg / ml) for a further 48 h. The cells were then fixed and stained with the antibody specific for YT521-B, as described in Example 4.

FIG. 2B (right column) shows that in the tumor cells, after treatment with the anti-tumor agent tamoxifen, the characteristic nuclear areas could be localized again by means of the ER or DR protein staining. The same thing happened after treatment with the differentiation agents sodium butyrate and PMA (Fig. 2B, middle columns). Furthermore, it was shown that nuclear ER- or DR-Protem-specific areas in cell cycle studies during the middle to late Gl phase and during the S phase, but not during the G2 / M phase and the early Gl phase were localizable. As a control, the differentiation states were verified with conventional staining using Olrot 0 after fixation of the cells with 2% formaldehyde and subsequent observation using phase contrast microscopy.

It could thus be shown that the ER and DR protems and their determinations could be used excellently as markers. This not only for the diagnosis of pathological conditions, but also for the identification of the differentiation state and / or the cell cycle state of a cell as well as for the testing of potentially therapeutically active substances or agents.

Example 6

Transfection or transformation with DNA encoding ER or DR proteins

3 × 10 ⁵ cells (for example HEK293, COS7 or BHK cells) were sown in a 3.5 cm culture dish and with a suitable amount of plasmid construct which contained the DNA coding for the ER or DR protein , subjected to a transfection or transformation. For example, HEK293 cells with 0.5 μg - 1 μg plasmid DNA were described using the calcium precipitation method as described (0. Nayler et al.,

Bioche. J., Vol. 326, pp. 693-700 (1997)). The cells were harvested 24 hours after transfection. COS7 or BHK cells were treated with 10 μl Superfect reagent (Qiagen, Hilden, Germany) according to the manufacturer's instructions using 1.5 μg plasmid DNA (0.5 μg of the cloned Construct and 1 μg of empty Camer vector). For example, the vector pEGFP-YT521-B obtained in Example 1 was used as expression constructs.

Example 7

Determination of the transcription activity of a cell

Cytological investigations showed that the characteristic nuclear areas of concentrated ER and DR prototypes co-localized with focal transcription sites. In order to be able to assess the transcriptional activity of a cell with regard to ER or DR proteins as markers, the outflow of known transcription or translation inhibitors was examined.

For this purpose, C0S7 cells, which were transiently expressed according to the method EGFP-YT521-B described in Example 6 as an example of a protein which contains ER-rich domains, were used and subjected to a treatment of different inhibitors. To the individual

Treatments included α-amanitm (blocks transcription by directly inhibiting RNA polymerase II; conditions: 50 μg / ml for 5 h), 5, 6-dιchloro- 1-ß-rιbofuranosyl-benzιmιdazol ("DRB", blocks the Transcription by inhibition of a kmase m in the upper one

Signal chain for RNA polymerase II; Conditions: 75 μm DRB for 3 h), cycloheximide ("Cyclo", only blocks RNA polymerase I; conditions: 100 μg / ml for 5 h) and Akmomycm D ("ActD", binds to GC-rich double-stranded DNA, allowed RNA intimation, but blocks RNA elongation;

Conditions: (a) 0.04 μg / ml for 3 h ("ActD low"), (b) 50 μg / ml for 3 h ("ActD high"), and (c) as (b), but after 2 h of incubation Removal of the high ActD concentration ("ActD high + freed"). The results are shown graphically in FIG. 4, the percentage of cells in which ER or DR domains could be located being plotted in relation to the treatment of the above-mentioned inhibitors against an untreated standard. The proportion of positive cells was determined under the fluorescence microscope by numbers of individual cells in three independent experiments per standard or inhibitor approach. The data show the averages of the three independent experiments (+/- standard deviation), with 150 cells each being paid. The results show that Actmomycm D dissolves the defined, ER- or DR-protein-specific areas in the cell nucleus. This sensitivity to Akmomycm D is reversible, however, since a release of the cells from this inhibitor increases the nuclear, localizable areas again. However, a low Actmomycm concentration or cycloheximide treatment showed no change in the number of cells in which nuclear regions of ER or DR proteins could be localized. α-Amanitm showed only a slight reduction in the proportion of cells which were positive in relation to nuclear, ER or DR protein-specific areas.

The determination of the ER or DR protein according to the invention can therefore also be used very useful for determining the transcription activity of a cell.

Claims

claims

1. A method for the diagnosis of cancer and / or neurodegenerative disease states, characterized in that proteins with domains rich in glutamate / Argmm or aspartic acid / Argmm rich (ER-Proteme or DR-Proteme) are determined.

2. The method according to claim 1, characterized in that the determination includes the examination of whether or to what extent ER or DR proteins can be localized in cellular, nuclear areas.

3. The method according to claim 1 or 2, characterized in that the determination of the ER or DR proteins is carried out immunocytometric.

4. The method according to any one of the preceding claims, characterized in that the ER or DR proteins determined in the method are those which are involved in the pre-mRNA splicing process and / or in the formation of the transcriptosomal complex.

5. The method according to any one of the preceding claims, characterized in that the ER Protem determined in the method is YT521 or its splice variant is YT521-B.

6. The method according to any one of the preceding claims, characterized in that breast cancer is diagnosed.

7. A method for examining the transcription activity, the differentiation stage or the cell cycle stage of a cell, characterized in that proteins with

Glutammic acid / Argmm-rich or aspartic acid / Argmm- rich domains (ER-Proteme or DR-Proteme) can be determined.

8. The method according to claim 7, wherein the determination is carried out as specified in one of claims 2 to 5.

9. A method for testing therapeutically active substances, comprising the examination of a change in proteins with domains rich in glutamate / Argmm or aspartic acid / Argmm rich (ER-Proteme or DR-Proteme) due to an action by the optionally therapeutically active substance.

10. The method according to claim 9, characterized in that therapeutically active substances against cancer and / or neurodegenrative disease states are tested.

11. The method according to claim 9 or 10, characterized in that it is examined whether or to what extent the localization of the ER or DR proteins changes in the cellular, nuclear areas.

12. The method according to any one of claims 9 to 11, characterized in that the ER or DR proteins examined in the method are those which are involved in the pre-mRNA splicing process and / or in the formation of the transcriptosomal complex.

13. The method according to any one of claims 9 to 12, characterized in that the ER protein examined in the method

YT521 or its splice variant is YT521-B.

14. Antibody, which is specific against a protein with glutamic acid / Argmm-rich or aspartic acid / Argimn-rich domain (ER-Protem or DR-Protem).

15. Antibody according to claim 14, characterized in that the ER or DR protein is one which is involved in the pre-mRNA splicing process and / or in the formation of the transcriptosomal complex.

16. Antibody according to claim 14, characterized in that the ER protein YT521 or its splice variant YT521-B

17. Use of an antibody according to one of claims 14 to 16 in a method according to claim 1, a method according to claim 7 or a method according to claim 9.

18. Mammalian cell which is transformed by a DNA which codes for a protein with glutamic acid / Argmm-rich or aspartic acid / Argmm-rich domain (ER-Protem or DR-Protem).

19. Mammalian cell according to claim 18, characterized in that the DNA codes for an ER or DR protein which is involved in the pre-mRNA splicing process and / or in the formation of the transcriptosomal complex.

20. Mammalian cell according to claim 18 or 19, characterized in that the DNA codes for the ER prototype YT521 or its splice variant YT521-B.

21. Mammalian cell according to one of claims 18 to 20, characterized in that the DNA for transformation is merted in a vector suitable for transformation.

22. Mammalian cell according to claim 21, characterized in that a DNA is additionally merted in the vector, which codes for em detection marker protein.

23. mammalian cell according to any one of claims 18 to 22, characterized in that it is of human origin.

24. Use of a mammalian cell according to one of claims 18 to 23, a method for testing therapeutically active substances.

25. Use according to claim 24, characterized in that the tested substances are said to be effective against cancer and / or neurodegenrative disease states.